The present disclosure relates to the field of terahertz communication, and in particular, to a terahertz carrier sending apparatus and a terahertz carrier receiving apparatus.
With rapid growth of traffic in a network data center, a requirement for a transmission rate between devices in the data center is increasingly high, and a large quantity of high-speed cables are required for interconnection between cabinets in the data center and inside the cabinets. Currently, one connection mode is using a direct attach copper cable. However, as operating frequency increases, an increased metal loss greatly limits a transmission distance and a transmission rate of the copper cable. Another connection mode is using an active optical cable. However, because optical-to-electrical conversion is required for transmitting and receiving, power consumption and costs are greatly increased.
Currently, there is still another interconnection mode, that is, using a terahertz (THz) frequency band as a carrier, and using a terahertz transmission line as a transmission medium, to perform interconnection in the data center and another short-distance high-speed communication scenario. At an interface between the terahertz transmission line and a communication device, a terahertz signal in a radio frequency transceiver chip is usually guided into a resonant cavity of a metal connector through a microstrip, and an electromagnetic signal is coupled to the terahertz transmission line. This type of connector introduces a reflection resonance point. As a result, coupling efficiency and operating bandwidth are greatly reduced.
Embodiments of the present disclosure provide a terahertz carrier sending apparatus and a terahertz carrier receiving apparatus, to implement efficient electromagnetic coupling and improve data transmission bandwidth.
According to a first aspect, an embodiment of the present disclosure provides a terahertz carrier sending apparatus, including a feed transmission line, a mode excitation structure, a mode conversion structure, a terahertz transmission line, and a circuit board. The feed transmission line is configured to: receive an electrical signal sent by a radio frequency sending circuit, and transmit the electrical signal to the mode excitation structure. The mode excitation structure is configured to excite a terahertz signal based on the received electrical signal. The mode conversion structure includes an inner cavity whose inner wall is metal, and the mode excitation structure and one end of the terahertz transmission line are located in the inner cavity, so that the terahertz signal excited by the mode excitation structure is coupled into the terahertz transmission line. The terahertz transmission line is configured to transmit the terahertz signal. The circuit board is configured to fasten the feed transmission line and the mode excitation structure, the mode conversion structure further includes a positioning slot configured to insert a part of the circuit board and the mode excitation structure into the inner cavity of the mode conversion structure. A plurality of metal through holes are distributed on both sides of the mode excitation structure. A boundary of the positioning slot is metal and press-fitted on the metal through holes on the both sides of the mode excitation structure. In this way, efficient electromagnetic coupling is implemented, and data transmission bandwidth is improved.
In a possible design, the feed transmission line, the mode excitation structure, and the metal through hole are located on the circuit board. Therefore, coupling efficiency can be further improved.
In still another possible design, the feed transmission line, the mode excitation structure, and the metal through hole are located on a package substrate of a radio frequency sending chip, and a metal through hole part on the package substrate and a corresponding part of the printed circuit board (PCB) board are press-fitted by the boundary of the positioning slot. Therefore, coupling efficiency can be further improved.
In still another possible design, the feed transmission line, the mode excitation structure, and the metal through hole are located on a radio frequency sending chip, and a metal through hole part on the chip and a corresponding part of the PCB board are press-fitted by the boundary of the positioning slot. Therefore, coupling efficiency can be further improved.
In still another possible design, the radio frequency sending chip further includes an impedance matching structure configured to match impedance between the feed transmission line and the mode excitation structure. Therefore, coupling efficiency can be further improved.
In still another possible design, a plurality of metal through holes are distributed on both sides of the impedance matching structure. Therefore, coupling efficiency can be further improved.
In still another possible design, the impedance matching structure includes a uniform substrate integrated waveguide and a tapered substrate integrated waveguide, and distances between metal through holes on both sides of the tapered substrate integrated waveguide also gradually change accordingly. Therefore, coupling efficiency can be further improved.
In still another possible design, a radiation phase center of the mode excitation structure coincides with an axial direction of the mode conversion structure. Therefore, coupling efficiency can be further improved.
According to a second aspect, an embodiment of the present disclosure provides a terahertz carrier receiving apparatus, including a terahertz transmission line, a mode conversion structure, a mode excitation structure, a feed transmission line, and a circuit board. The terahertz transmission line is configured to receive a terahertz signal. The mode conversion structure includes an inner cavity whose inner wall is metal, and the mode excitation structure and one end of the terahertz transmission line are located in the inner cavity, so that the terahertz signal in the terahertz transmission line is coupled into the mode excitation structure. The mode excitation structure is configured to: convert the terahertz signal into an electrical signal, and send the electrical signal to the feed transmission line. The feed transmission line is configured to transmit the electrical signal to a radio frequency receiving circuit. The circuit board is configured to fasten the feed transmission line and the mode excitation structure. The mode conversion structure further includes a positioning slot configured to insert a part of the circuit board and the mode excitation structure into the inner cavity of the mode conversion structure. A plurality of metal through holes are distributed on both sides of the mode excitation structure. A boundary of the positioning slot is metal and press-fitted on the metal through holes on the both sides of the mode excitation structure. In this way, efficient electromagnetic coupling is implemented, and data transmission bandwidth is improved.
In still another possible design, the feed transmission line, the mode excitation structure, and the metal through hole are located on the circuit board. Therefore, coupling efficiency can be further improved.
In still another possible design, the feed transmission line, the mode excitation structure, and the metal through hole are located on a package substrate of a radio frequency receiving chip, and a metal through hole part on the package substrate and a corresponding part of the PCB board are press-fitted by the boundary of the positioning slot. Therefore, coupling efficiency can be further improved.
In still another possible design, the feed transmission line, the mode excitation structure, and the metal through hole are located on a radio frequency receiving chip, and a metal through hole part on the chip and a corresponding part of the PCB board are press-fitted by the boundary of the positioning slot. Therefore, coupling efficiency can be further improved.
In still another possible design, the radio frequency receiving chip further includes an impedance matching structure configured to match impedance between the feed transmission line and the mode excitation structure. Therefore, coupling efficiency can be further improved.
In still another possible design, a plurality of metal through holes are distributed on both sides of the impedance matching structure. Therefore, coupling efficiency can be further improved.
In still another possible design, the impedance matching structure includes a uniform substrate integrated waveguide and a tapered substrate integrated waveguide, and distances between metal through holes on both sides of the tapered substrate integrated waveguide also gradually change accordingly. Therefore, coupling efficiency can be further improved.
In still another possible design, a radiation phase center of the mode excitation structure coincides with an axial direction of the mode conversion structure. Therefore, coupling efficiency can be further improved.
To make objectives, technical solutions, and advantages of the present disclosure clearer, the following further describes implementations of the present disclosure in detail with reference to accompanying drawings.
A terahertz carrier sending apparatus and a terahertz carrier receiving apparatus provided in embodiments of the present disclosure may be used in a high-speed interconnection scenario, for example, a data center. As shown in
When a message is sent, a to-be-sent service signal enters the radio frequency sending chip 204 after being processed by the baseband signal processing chip 203, and the electromagnetic coupling structure 206 is configured to couple, to the terahertz transmission line 207 for sending, a carrier signal output by the radio frequency sending chip 204. In addition, when a message is received, the electromagnetic coupling structure 206 couples, to the radio frequency receiving chip 205, a carrier signal received through the terahertz transmission line 207, and the baseband signal processing chip 203 processes the carrier signal to obtain a service signal. The electromagnetic coupling structure generally includes a feed transmission line, a mode excitation structure, and a mode conversion structure. A coupling structure may be implemented on a PCB board, may be directly coupled on a chip, or may be coupled on a package structure of a chip.
The baseband signal processing chip 203, the radio frequency sending chip 204, and the radio frequency receiving chip 205 may also be packaged in a service device. Alternatively, the radio frequency sending chip 204 and the radio frequency receiving chip 205 may be integrated into one chip for implementation. Bidirectional transmission and reception may also be implemented by using one terahertz transmission line 207. To be specific, two different terahertz frequencies are used to carry terahertz signal transmission in two directions. In this case, one mode conversion structure 206 may be configured for bidirectional coupling, and may not only couple a to-be-sent carrier signal into a terahertz transmission line, but also couple a carrier signal received through the terahertz transmission line into a radio frequency receiving chip.
A carrier signal of a radio frequency sending chip 302 is fed into a uniform substrate integrated waveguide 304 through a feed microstrip 303 with a tapered structure, to convert from a quasi-TEM mode of a carrier signal in a plane feed microstrip structure to a quasi-TE10 mode of a carrier signal in the uniform substrate integrated waveguide. Further, the uniform substrate integrated waveguide 304 is connected to a tapered substrate integrated waveguide 305 for better impedance matching with a mode excitation structure 306. The mode excitation structure 306 in
An inner cavity of a mode conversion structure 312 is cylindrical, an inner wall of the mode conversion structure 312 is metal, an eccentric position at one end of the mode conversion structure 312 is provided with a rectangular positioning slot 311, and the other end of the mode conversion structure 312 may be inserted into a terahertz transmission line 313. The PCB board 301 is inserted into the positioning slot 311, so that a carrier signal sent by the end-fire antenna may be coupled into the terahertz transmission line 313 that is inserted into the inner cavity of the mode conversion structure 312.
Metal through holes 307 are arranged on both sides of the substrate integrated waveguide 304/305 and the end-fire antenna 306. In this way, when the PCB board is inserted into the positioning slot, a boundary of the positioning slot is press-fitted by the metal through holes. Because the boundary of the positioning slot 311 also uses a metal material, cavity leakage of an electromagnetic wave in the mode conversion structure 312 is reduced, and efficiency of coupling an electromagnetic signal from the end-fire antenna to the terahertz transmission line is improved. The tapered substrate integrated waveguide is used for feeding, to improve a broadband range of impedance matching.
Some related dimensions of a feed tapered section, the metal through hole, the positioning slot need to satisfy related conditions, to better implement carrier signal coupling. Refer to
A feed tapered section of a tapered slot end-fire antenna needs to satisfy:
Ws=Wu+N×iy, Tl=N×(d+iz) (Formula 1)
Parameters in the formula 1 include a width Ws between through holes of a substrate integrated waveguide at a feed tapered section, a width Wu between through holes of the substrate integrated waveguide at a uniform section, a quantity N of metal through holes at the tapered section, a tapered distance iy of tapered metal through holes, a length Tl of the substrate integrated waveguide at the feed tapered section, a metal through hole diameter d, and a metal through hole spacing iz.
A tapered slot end-fire antenna and metal through holes on both sides of the tapered slot end-fire antenna need to satisfy:
Wl≤Ws, L=M×(d+iz) (Formula 2)
Parameters in the formula 2 include a bottom patch width Wl of the forward and reverse linearly tapered slot antenna, a width Ws between through holes of the substrate integrated waveguide at the feed tapered section, a length L of the forward and reverse linearly tapered slot antenna, a quantity M of metal through holes arranged on both sides of the forward and reverse linearly tapered slot antenna, a metal through hole diameter d, and a metal through hole spacing iz.
A position relationship between a metal mode converter and the PCB needs to satisfy:
Ct=St+2×Mt, Cl≥L (Formula 3)
Parameters in the formula 3 include a slot height Ct of the metal mode converter, a thickness St of a middle layer of the PCB board, a thickness Mt between an upper metal layer and a lower metal layer of the PCB board, a slot depth Cl of the metal mode converter, and a length L of the forward and reverse linearly tapered slot antenna.
According to embodiments of the present disclosure, leakage of an electromagnetic wave in the mode conversion structure is reduced, and efficiency of coupling an electromagnetic signal from the end-fire antenna to the terahertz transmission line is improved. For example, coupling efficiency may be learned from a diagram of electric field mode distribution of electromagnetic simulation. Specifically, simulation is performed based on embodiments shown in
According to the foregoing related dimensions, a schematic diagram of electric field mode distribution shown in
As shown in
As shown in
A carrier signal of a radio frequency sending chip is fed into a uniform substrate integrated waveguide 703 through a feed microstrip 702 with a tapered structure, to convert from a quasi-TEM mode of a carrier signal in a plane feed microstrip structure to a quasi-TE10 mode of a carrier signal in the uniform substrate integrated waveguide. Further, the uniform substrate integrated waveguide 703 is connected to a tapered substrate integrated waveguide 704 for better impedance matching with a mode excitation structure 705. The mode excitation structure 705 in
An inner cavity of a mode conversion structure 712 has a rectangular cross section, an inner wall of the mode conversion structure 712 is metal, an eccentric position at one end of the mode conversion structure 712 is provided with a rectangular positioning slot 711, and the other end of the mode conversion structure 712, that is, a cylindrical waveguide 714, may be inserted into a terahertz transmission line 715. A PCB board 701 is inserted into the positioning slot 711, so that a carrier signal sent by the end-fire antenna may be coupled into the terahertz transmission line 715 that is inserted into the inner cavity of the mode conversion structure 712.
Metal through holes 706 are arranged on both sides of the substrate integrated waveguide 703/704 and the end-fire antenna 705. In this way, when the PCB board is inserted into the positioning slot, a boundary of the positioning slot is press-fitted by the metal through holes. Because the boundary of the positioning slot 711 also uses a metal material, cavity leakage of an electromagnetic wave in the mode conversion structure 712 is reduced, and efficiency of coupling an electromagnetic signal from the end-fire antenna to the terahertz transmission line is improved. The tapered substrate integrated waveguide is used for feeding, to improve a broadband range of impedance matching.
Similarly, some related dimensions of a feed tapered section, the metal through hole, and the positioning slot need to satisfy related conditions, to better implement carrier signal coupling. Refer to
Similarly, embodiments shown in
According to the foregoing related dimensions, a schematic diagram of electric field mode distribution shown in
As shown in
The radio frequency sending chip 1102 feeds a carrier signal into a uniform substrate integrated waveguide 1104 through a feed microstrip 1103 with a tapered structure, and is further connected to a tapered substrate integrated waveguide 1105, to better match impedance of a mode excitation structure 1106. An eccentric position at one end of the mode conversion structure 1112 is provided with a rectangular positioning slot 1111, and the other end of the mode conversion structure 1112 is inserted into a terahertz transmission line 1113. The PCB board 1101 and the package substrate 1108 are inserted into the positioning slot 1111, so that a carrier signal sent by an end-fire antenna may be coupled to the terahertz transmission line 1113 that is inserted into an inner cavity. Metal through holes 1107 are arranged on both sides of the substrate integrated waveguide 1104/1105 and the end-fire antenna 1106. A specific design and a constraint condition are similar to those described above.
The radio frequency sending chip 1202 feeds a carrier signal into a uniform substrate integrated waveguide 1204 through a feed microstrip 1203 with a tapered structure, and is further connected to a tapered substrate integrated waveguide 1205, to better match impedance of a mode excitation structure 1206. An eccentric position at one end of the mode conversion structure 1212 is provided with a rectangular positioning slot 1211, and the other end of the mode conversion structure 1212 is inserted into a terahertz transmission line 1213. The PCB board 1201, the package substrate 1208, and the radio frequency transceiver chip 1202 are inserted into the positioning slot 1211 together, so that a carrier signal sent by an end-fire antenna may be coupled to the terahertz transmission line 1213 that is inserted into an inner cavity of the mode conversion structure 1212. Metal through holes 1207 are arranged on both sides of the substrate integrated waveguide 1204/1205 and the end-fire antenna 1206. A specific design and a constraint condition are similar to those described above.
In embodiments shown in
Although the present disclosure is described with reference to embodiments, in a process of implementing the present disclosure that claims protection, persons skilled in the art may understand and implement another variation of the disclosed embodiments by viewing the accompanying drawings, disclosed content, and the accompanying claims. In the claims, “comprising” does not exclude another component or another step, and “a” or “one” does not exclude a case of multiple.
Although the present disclosure is described with reference to specific features and embodiments thereof, apparently, various modifications and combinations may be made to the present disclosure. Correspondingly, the specification and accompanying drawings are merely example descriptions of the present disclosure defined by the appended claims, and is considered as any of or all modifications, variations, combinations or equivalents that cover the scope of the present disclosure. It is clear that a person skilled in the art may make various modifications and variations to the present disclosure without departing from the scope of the present disclosure. The present disclosure is intended to cover these modifications and variations provided that they fall within the scope of protection defined by the following claims and their equivalent technologies.
Number | Date | Country | Kind |
---|---|---|---|
202011632320.0 | Dec 2020 | CN | national |
This application is a continuation of International Patent Application No. PCT/CN2021/140105 filed on Dec. 21, 2021, which claims priority to Chinese Patent Application No. 202011632320.0 filed on Dec. 31, 2020. The disclosures of the aforementioned applications are hereby incorporated by reference in their entireties.
Number | Date | Country | |
---|---|---|---|
Parent | PCT/CN2021/140105 | Dec 2021 | US |
Child | 18344251 | US |